JP6828316B2 - Merge support device - Google Patents

Description

The present disclosure relates to technologies that support merging.

In recent years, there has been known a technique for safely merging vehicles in a merging area on a road. The confluence area is the area where the branch line merges with the main line of the road.
In Patent Document 1, the roadside infrastructure provided on the main line and the branch line detects a merged vehicle traveling on the main line or a merging vehicle traveling on the branch line, respectively, and secures a space for merging the merging vehicle into the main line. It is described that the merging vehicle and the merging vehicle are notified of the vehicle speed and the priority so as to be performed.

Japanese Unexamined Patent Publication No. 2015-102893

However, in the technique of Patent Document 1, the notification is given before the confluence region based on the information detected before the confluence region. For this reason, even if the merging vehicle and the merging vehicle are traveling according to the notification so that a space for merging is secured in the merging area, it is expected that the merging vehicle will suddenly cut into the space in the merging area, which hinders the merging. There is a problem that a danger occurs when a vehicle that operates improperly occurs.

Therefore, in view of such problems, it is an object of the present invention to provide a technique that contributes to safety.

The merging support device (50) of the present disclosure includes an inhibition acquisition unit (S45), a merging acquisition unit (S50), and an output unit (S65). The obstruction acquisition unit is configured to acquire obstruction information indicating that an obstructive object indicating an object moving so as to narrow the space in front of the lane in which the own vehicle is traveling exists around the own vehicle. The merging acquisition unit indicates that the own vehicle is located in the merging area representing the area where the second lane indicating a lane different from the first lane merges with the first lane indicating the lane in which the own vehicle is traveling. It is configured to acquire area information. The output unit is configured to output caution information that calls attention when the confluence area information is acquired and the inhibition information is acquired.

According to such a merging support device, when the own vehicle is located in the merging area, if there is an obstructing object around the own vehicle, the caution information for calling attention is output. Therefore, when there is an obstructing object in the merging region that can hinder smooth merging, attention can be drawn by the caution information. As a result, it is possible to provide merging support that contributes to safety.

In addition, the reference numerals in parentheses described in this column and the scope of claims indicate the correspondence with the specific means described in the embodiment described later as one embodiment, and the technical scope of the present disclosure is defined. It is not limited.

The block diagram which shows the structure of the merging support system of this disclosure. The figure explaining the confluence point. A flowchart showing the merging support process. The flowchart which shows the obstruction vehicle determination process. The figure explaining the obstruction vehicle list. The figure explaining the effect by the merging support of 1st Embodiment. The figure explaining the situation where safe merging is suppressed in a merging area. A flowchart showing platooning. The figure explaining the instruction distance. The figure explaining how the inter-vehicle communication information is transmitted and received between vehicles capable of inter-vehicle communication. The figure explaining the formation instruction. The figure explaining the operation by the formation instruction. The figure explaining the effect by the merging support of 2nd Embodiment.

Hereinafter, embodiments of the present disclosure will be described with reference to the drawings.
[1. First Embodiment]
[1-1. Constitution]
The merging support system 10 shown in FIG. 1 is a system mounted on a vehicle to support merging.

As shown in FIG. 2, the merging here refers to a vehicle traveling in the second lane 62 in the merging area 71 indicating the area where the second lane 62 representing the branch line merges with the first lane 61 representing the main line. Indicates that the merging vehicle 9 moves to the first lane 61.

The lane here is an area on the road and represents an area defined by a lane marking line that divides the road such as a white line or a yellow line. In the following, lanes are also referred to as lanes. The merging support system 10 of the present embodiment provides support for safely merging the merging vehicle 9 that is going to move to the first lane 61, that is, the lane in which the own vehicle 1 is traveling. The vehicle equipped with the merging support system 10 is also referred to as the own vehicle 1.

The merging support system 10 shown in FIG. 1 includes a control unit 50. The merging support system 10 includes a GPS receiver 11, a radar 12, a camera 13, a vehicle speed sensor 14, a map database 15, road data 151, an inter-vehicle communication device 20, and a wireless communication device 30. You may be. GPS indicates a global positioning system.

The GPS receiver 11 is a well-known device that detects the position of the own vehicle 1 based on radio waves transmitted from GPS satellites.
The radar 12 transmits electromagnetic waves such as radio waves to the surroundings of the own vehicle 1 and receives the reflected waves to detect an object existing around the own vehicle 1. An object represents a tangible object. The tangible object may include, for example, a person, a vehicle, or the like.

One or a plurality of cameras 13 are provided to take an image of the surroundings of the own vehicle 1.
The vehicle speed sensor 14 is a well-known sensor that detects the traveling speed of the own vehicle 1.
The map database 15 is a database that stores well-known map information in which latitude / longitude on the earth and road data are associated with each other. The road data 151 is associated with various information such as the position of lanes on the road, the number of lanes, the position of the merging area 71, and the position of the tollhouse provided on the branch line merging into the merging area 71. The position of the merging region 71 may include a merging start position 711 where the main line and the branch line start merging, and a merging end position 712 where the merging ends.

The vehicle-to-vehicle communication device 20 is a well-known communication device for exchanging information with other vehicles. The vehicle-to-vehicle communication device 20 has a function of exchanging information about the own vehicle 1 such as the position, the vehicle number, and the vehicle speed of the own vehicle 1 with another vehicle. The vehicle number referred to here indicates a number on the license plate of the vehicle, but the vehicle number may be any information such as a vehicle ID that can individually identify the vehicle.

The wireless communication device 30 is a well-known communication device for exchanging information with an external device that collects and distributes various information of vehicles on the road, such as a center and roadside infrastructure. The wireless communication device 30 may transmit information about the own vehicle 1, such as the position of the own vehicle 1, the vehicle number, the vehicle speed, and the like.

The control unit 50 is mainly composed of a well-known microcomputer having a CPU 51 and a semiconductor memory (hereinafter, memory 52) such as a RAM, a ROM, and a flash memory. Various functions of the control unit 50 are realized by the CPU 51 executing a program stored in a non-transitional substantive recording medium. In this example, the memory 52 corresponds to a non-transitional substantive recording medium in which a program is stored. The non-transitional substantive recording medium means to remove electromagnetic waves from the recording medium. In addition, by executing this program, the method corresponding to the program is executed. The number of microcomputers constituting the control unit 50 may be one or a plurality.

The control unit 50 includes a function of performing merging support as one of the functions realized by the CPU 51 executing a program. The method for realizing the function in the control unit 50 is not limited to software, and some or all of the elements may be realized by using hardware in which a logic circuit, an analog circuit, or the like is combined.

[1-2. processing]
Next, the merging support process executed by the control unit 50 will be described with reference to the flowchart shown in FIG. As shown in FIG. 2, the merging support process is a process for safely merging the merging vehicle 9 in the space 81 in front of the own vehicle 1. The merging support process is started, for example, when the power of the merging support system 10 is turned on, and is repeated thereafter. If the subject is omitted in the description of the process, the control unit 50 is used as the subject.

In the merging support process, the control unit 50 first acquires the own vehicle 1 information in S10. The own vehicle 1 information represents information about the own vehicle 1. The information referred to here may include the vehicle speed, the current position of the own vehicle 1 (hereinafter, the own vehicle position), and the like. As the vehicle speed, the detection result by the vehicle speed sensor 14 is used. As the position of the own vehicle, the detection result by the GPS receiver 11 is used.

The control unit 50 acquires surrounding information in S15. The surrounding information represents information about other vehicles located around the own vehicle 1. Hereinafter, other vehicles are also referred to as other vehicles. It should be noted that the surroundings referred to here may include, for example, a range in which radio waves from vehicle-to-vehicle communication can reach. Vehicles may include four-wheeled vehicles such as passenger cars and trucks, and two-wheeled vehicles such as motorcycles.

Further, the information referred to here may include a moving direction, a position, a speed, and the like. The moving direction represents the moving direction. The position may be indicated by either an absolute position or a position relative to the position of the own vehicle 1. The speed may be indicated by either an absolute speed or a relative speed indicating a speed relative to the own vehicle 1. In the present embodiment, the output result by the radar 12 is used to acquire the moving direction, the position, and the speed. In addition, instead of the position, information such as the direction and the distance may be included in the surrounding information.

In S20, the control unit 50 executes the obstruction vehicle determination process. The obstructing vehicle determination process is a process for determining whether or not an obstructing vehicle exists around the own vehicle 1. For example, as shown in FIG. 7, which will be described later, the obstructing vehicle 8 represents another vehicle that the own vehicle 1 moves so as to narrow the space 81 in front of the lane in which the vehicle is traveling.

The term "front" as used herein means the traveling direction of the own vehicle 1. The space represents an area where no other object, that is, another vehicle exists. The periphery of the own vehicle 1 referred to here includes front and rear with respect to the traveling direction of the own vehicle 1 and right and left with respect to the traveling direction of the own vehicle 1. Moving so as to narrow the space means moving so that the distance between the first lane 61 and another vehicle in the width direction of the road becomes shorter, or the distance between the own vehicle 1 and another vehicle in the extending direction of the road. Includes moving to shorten.

In the following, the first lane 61 means the lane in which the own vehicle 1 is traveling, and the second lane 62 means a branch line that joins the first lane 61 as the main line. In the obstruction vehicle determination process, it is determined whether or not the other vehicle moves so as to narrow the space based on the moving direction and position of the other vehicle.

In the obstruction vehicle determination process, as shown in FIG. 4, in S100, the control unit 50 is in the first lane 61 based on the position of the own vehicle acquired in S10 and the position of another vehicle acquired in S20. In, it is determined whether or not another vehicle is located immediately before the own vehicle 1. The term "positioned immediately before" as used herein means that the vehicle is located in front of the vehicle 1 in the traveling direction and is located closest to the vehicle 1. The control unit 50 shifts the process to S110 when another vehicle is located immediately before the own vehicle 1 in the first lane 61, and shifts the process to S105 when it is not located.

In S105, the control unit 50 deletes the obstruction vehicle information in which the obstruction pattern described later indicates "deceleration" from the obstruction vehicle list described later, and records the deleted obstruction vehicle list as a new obstruction vehicle list in the memory 52. .. Then, the process is transferred to S120.

In S110, the control unit 50 determines whether or not another vehicle is located immediately before the own vehicle 1 in the first lane 61 and the other vehicle is decelerating. Here, the relative speed of the other vehicle with respect to the own vehicle 1 acquired in S15 is recorded in the memory 52 each time it is acquired during a predetermined period. When the relative speed of the other vehicle recorded in the memory 52 decreases with the passage of time, the control unit 50 determines that the other vehicle is decelerating.

In the control unit 50, when another vehicle is located immediately before the own vehicle 1 in the first lane 61 and the speed of the other vehicle decreases with the passage of time, the other vehicle takes up space. It is determined that the vehicle moves so as to narrow the space, and the processing is shifted to S115 with the other vehicle as the obstructing vehicle. Further, when another vehicle is located immediately before the own vehicle 1 in the first lane 61 but the other vehicle is not decelerating, the process is shifted to S120.

In S115, the control unit 50 determines that another vehicle located immediately before the own vehicle 1 in the first lane 61 and decelerating is an obstructive vehicle, generates obstruction information, and records it in the memory 52. .. The obstruction information represents information indicating that the obstructing vehicle exists around the own vehicle 1. That is, the obstruction information is recorded in the memory 52 only when the obstruction vehicle exists around the own vehicle 1.

Further, the control unit 50 generates the obstructed vehicle information indicating the information about the obstructed vehicle and records it in the memory 52. As shown in FIG. 5, for example, the obstructed vehicle information indicates information in which the vehicle number, position, obstruction pattern, degree of obstruction, etc. of the obstructing vehicle are associated with each other. The term "blocked vehicle list" as used below refers to information including one or more such blocked vehicle information.

Here, the vehicle number is the number of the vehicle license plate. The control unit 50 has a position of another vehicle acquired in S15 by a process different from the present obstruction vehicle determination process (hereinafter, another process) and a position of the other vehicle in the image captured by the camera 13. It may be configured to associate with. Then, it may be configured to acquire the information in which the vehicle number imaged by the camera 13 and the position of the vehicle having the vehicle number are associated with each other.

The vehicle number and position of the obstructing vehicle are not limited to this, and information acquired by, for example, vehicle-vehicle communication may be used.
The inhibition pattern refers to information indicating what kind of inhibition is being performed so as to narrow the space by the inhibition vehicle. In this step of shifting when another vehicle is located immediately before the own vehicle 1 in the first lane 61 and the other vehicle decelerates, for example, "deceleration" is recorded as an inhibition pattern. The inhibitory pattern may be expressed in any form as long as the plurality of inhibitory patterns can be identifiable. For example, the inhibitory pattern may be indicated numerically, such as the inhibitory pattern "1".

The degree of inhibition indicates the probability that the confluence is inhibited for each inhibition pattern. The correspondence relationship between the inhibition pattern and the degree of inhibition is recorded in advance in the memory 52 as the degree of inhibition correspondence information. The control unit 50 acquires and records the degree of inhibition corresponding to the inhibition pattern based on the degree of inhibition correspondence information. For example, as shown in FIG. 5, when the inhibition pattern is "deceleration", the inhibition degree may be set to 30% according to the inhibition degree correspondence information.

The degree of inhibition is not limited to the predetermined value such as 30% described above, and may be set arbitrarily. For example, when another vehicle is located immediately in front of the own vehicle 1 in the first lane 61 and the other vehicle decelerates, the deceleration degree of the vehicle is acquired, and as the deceleration degree increases. The degree of inhibition may be set so that the degree of inhibition is high. The degree of deceleration indicates the rate at which the vehicle speed decelerates in a predetermined time. In the inhibition degree correspondence information, when the inhibition pattern is "deceleration", the inhibition degree may be set so that the inhibition degree increases as the deceleration degree increases.

After recording the obstructed vehicle information in the memory 52, the control unit 50 ends the obstructed vehicle determination process.
In S120, the control unit 50 determines whether or not the other vehicle is located in the anti-adjacent lane 63 based on the position of the other vehicle acquired in S15 and the road data 151. The anti-adjacent lane 63 represents a lane adjacent to the first lane 61 and located opposite to the second lane 62. The control unit 50 shifts the process to S125 when no other vehicle is located in the anti-adjacent lane 63, and shifts the process to S130 when it is located.

In S125, the control unit 50 deletes the obstructed vehicle information indicating "interrupt approach" and "interrupt display" described later in the obstructed pattern from the obstructed vehicle list, and stores the deleted obstructed vehicle list as a new obstructed vehicle list. Record at 52. Then, the control unit 50 ends the present inhibition vehicle determination process.

In S130, the control unit 50 acquires the distance between lanes. As shown in FIG. 6, the inter-lane distance 631 indicates the distance from the position of the other vehicle 8 to the first lane 61. The distance between lanes 631 is calculated based on the positions of other vehicles acquired in S20 and the road data 151. The control unit 50 may be configured to acquire the inter-lane distance 631 calculated by another process, or the control unit 50 may be configured to calculate the inter-lane distance 631.

In S135, the control unit 50 determines whether or not another vehicle located in the anti-adjacent lane 63 is approaching the first lane 61. The control unit 50 determines that the vehicle is approaching the first lane 61 when the inter-lane distance 631 decreases with the passage of time.

The control unit 50 moves so that the other vehicle narrows the space when another vehicle is located in the anti-adjacent lane 63 and the distance between lanes 631 for the other vehicle decreases with the passage of time. It is determined that the other vehicle is used as an obstructing vehicle, and the processing is shifted to S140. Further, even if another vehicle is located in the anti-adjacent lane 63, if the inter-lane distance 631 for the other vehicle does not decrease with the passage of time, the process is shifted to S145.

In S140, the control unit 50 determines that another vehicle located in the anti-adjacent lane 63 and whose inter-lane distance 631 decreases with the passage of time is an obstructive vehicle, generates obstruction information, and generates memory 52. Record in. Further, similarly to S115, the obstructed vehicle information regarding the obstructed vehicle is generated and recorded in the memory 52.

Here, in this step of transitioning when another vehicle is located in the anti-adjacent lane 63 and the distance 631 between the lanes of the other vehicle decreases with the passage of time, for example, an "interrupt approach" is hindered. Record as. The inhibitory pattern may be indicated numerically, for example, the inhibitory pattern "2". Further, when the inhibition pattern is "interrupt approach", the inhibition degree may be associated with, for example, 30% by the inhibition degree correspondence information. The degree of inhibition is not limited to the predetermined value such as 30% described above, and may be set arbitrarily.

After recording the obstructed vehicle information in the memory 52, the control unit 50 shifts the process to S145.
In S145, the control unit 50 acquires image data showing an image of the surroundings of the own vehicle 1 from the camera 13.

In S150, the control unit 50 determines whether or not the object included in the image is a vehicle that has announced a lane change to the first lane 61, based on the acquired image data. The vehicle that has announced a lane change to the first lane 61 represents, for example, a vehicle 8 that operates a turn signal to indicate the first lane 61 side, as shown in FIG.

When identifying that the object is a vehicle in the image data, a well-known method such as pattern matching may be used. Further, the identification that the vehicle has announced a lane change to the first lane 61 may be performed based on the brightness in the image data. Since these are all well-known techniques, detailed description thereof will be omitted.

When the control unit 50 has another vehicle located in the anti-adjacent lane 63 and the other vehicle has announced a lane change to the first lane 61, the other vehicle takes up space. It is determined that the vehicle will move so as to be narrowed, and the processing is shifted to S155 with the vehicle as an obstructive vehicle. Further, even if another vehicle is located in the anti-adjacent lane 63, if the other vehicle has not announced a lane change to the first lane 61, the obstruction vehicle determination process is terminated.

In S155, the control unit 50 determines that the vehicle located in the anti-adjacent lane 63 and has announced the change of lane to the first lane 61 is an obstructive vehicle, and generates obstruction information for the obstructed vehicle. Record in the memory 52. Further, similarly to S115, the obstructed vehicle information regarding the obstructed vehicle is generated and recorded in the memory 52.

In this step of transitioning to the case where another vehicle is located in the anti-adjacent lane 63 and the other vehicle has announced a lane change to the first lane 61, for example, "interrupt display" is hindered. Record as a pattern.

The inhibitory pattern may be indicated numerically, for example, the inhibitory pattern "3". Further, when the inhibition pattern is "interrupt display", the inhibition degree may be associated with, for example, 80% as having a higher accuracy than "interrupt approach" according to the inhibition degree correspondence information. The degree of inhibition is not limited to the predetermined value such as 80% described above, and may be set arbitrarily.

After recording the obstructed vehicle information in the memory 52, the control unit 50 ends the obstructed vehicle determination process.

The explanation will be continued by returning to FIG. In S30, the control unit 50 determines whether or not the own vehicle 1 is located in the merging area 71 based on the current position of the own vehicle 1 and the road data 151. The merging area 71 represents an area in which the second lane 62, which is a lane different from the first lane 61 and is a branch line, is connected to the first lane 61, which is the lane in which the own vehicle 1 is traveling and is the main line. ..

The control unit 50 shifts the process to S40 when the own vehicle 1 is located in the merging area 71, and shifts the process to S45 when it is not located.
In S40, the control unit 50 generates the merging area information and records it in the memory 52. The merging area information means information indicating that the own vehicle 1 is located in the merging area 71.

The control unit 50 acquires inhibition information in S45. In this step, the control unit 50 acquires the inhibition information generated in S115, S140, and S155. As described above, the control unit 50 records the obstruction information in the memory 52 when the obstruction vehicle is located around the own vehicle 1, and does not record the obstruction information in the memory 52 when the obstruction vehicle is not located. It is configured as.

In S50, the control unit 50 acquires the merging area information. In S50, the control unit 50 acquires the merging area information generated in S40. As described above, the control unit 50 records the merging area information in the memory 52 when the own vehicle 1 is located in the merging area 71, and stores the merging area information in the memory 52 when the own vehicle 1 is not located in the merging area 71. It is configured not to record in.

In S55, the control unit 50 determines whether or not the inhibition information has been acquired and the merging area information has been acquired. If both the inhibition information and the merging area information are acquired, the process is shifted to S65, and if either one of the inhibition information and the merging area information is acquired, or if both of them are not acquired, the present End the merge support process.

In S60, the control unit 50 acquires the obstructed vehicle list from the memory 52. The obstruction vehicle list may include one or more obstruction vehicle information as described above. In S65, the control unit 50 outputs caution information when the confluence area information is acquired and the inhibition information is acquired. Attention information represents information that calls attention. The caution information may include, for example, inhibition information and some or all of the inhibition vehicle information in the inhibition vehicle list. Specifically, for example, a message notifying that an obstructing vehicle exists may be included as obstruction information. In addition, the vehicle number and position of the obstructed vehicle may be included as the obstructed vehicle information.

The output destination of the caution information may include, for example, an output device such as a display or a speaker in the own vehicle 1, another vehicle, a center, a roadside infrastructure, or the like. The control unit 50 outputs caution information and ends the main merging support process.

[1-3. effect]
According to the first embodiment described in detail above, the following effects are obtained.
(1a) In the above-mentioned merging support system 10, the control unit 50 has an obstructive object around the own vehicle 1 indicating an object moving so as to narrow the space 81 in front of the lane in which the own vehicle 1 is traveling. Inhibition information representing. Further, the own vehicle 1 is located in the merging area 71 representing the area where the first lane 61 indicating the lane in which the own vehicle 1 is traveling and the second lane 62 indicating a lane different from the first lane 61 merge. Acquires the merging area information indicating. Then, when the confluence area information is acquired and the inhibition information is acquired, the caution information calling attention is output.

According to such a merging support system 10, when the own vehicle 1 is located in the merging area 71, when an obstructing object exists around the own vehicle 1, that is, an unexpected interruption or the like is performed by the obstructing object. Output caution information that calls attention when there is a risk. Therefore, when there is an obstructing vehicle in the merging area 71 that can hinder smooth merging, for example, the own vehicle 1, another vehicle located around the own vehicle 1, or the merging vehicle 9 is determined by the caution information. Can call attention to. As a result, it is possible to provide merging support that contributes to safety.

That is, if there is a vehicle in the anti-adjacent lane 63 that operates the direction indicator so as to indicate the first lane 61 side as shown in FIG. 6, the vehicle is determined as the obstructing vehicle 8 and the caution information is given. It is output by vehicle-to-vehicle communication. Therefore, for example, the merging vehicle 9 that has received the caution information can take various measures such as changing the vehicle speed at the time of merging and shifting the merging position. As a result, even if the obstructing vehicle 8 suddenly moves so as to narrow the space 81 in front as shown in FIG. 7, it is suppressed that the obstructing vehicle 8 prevents the merging.

The vehicles located around the own vehicle 1 are not necessarily limited to vehicles capable of inter-vehicle communication and wireless communication. Vehicles located around the own vehicle 1 may include vehicles that do not perform vehicle-to-vehicle communication or wireless communication. When the obstructing vehicle 8 is not a vehicle capable of vehicle-to-vehicle communication or wireless communication, it is difficult to support the merging vehicle 9 to safely join the vehicle because the surrounding information that can be acquired by the vehicle is limited. Is.

According to the present disclosure, the merging vehicle 9 is in the space 81 in front of the own vehicle 1 by calling attention to the obstructing vehicle 8 to the own vehicle 1 and the merging vehicle 9 located around the obstructing vehicle 8. Can be merged more safely.

(1b) In the above-mentioned merging support system 10, the control unit 50 may output caution information by wireless communication using the vehicle-to-vehicle communication device 20 and the wireless communication device 30.
According to such a merging support system 10, since the caution information is output by wireless communication, the caution information can be transmitted to other than the own vehicle 1.

(1c) In the above-mentioned merging support system 10, the control unit 50 may output caution information by vehicle-to-vehicle communication using a vehicle-to-vehicle communication device.
According to such a merging support system 10, caution information is output by vehicle-to-vehicle communication, so that attention is paid to vehicles around the own vehicle 1 in the first lane 61, merging vehicles 9 traveling in the second lane 62, and the like. It is possible to output information. As a result, it becomes possible to call attention to the vehicles around the own vehicle 1 and the merging vehicle 9.

(1d) In the above-mentioned merging support system 10, the control unit 50 may acquire the moving direction and the position of the object. Further, it may be determined whether or not the object moves so as to narrow the space based on the moving direction and the position of the object. Further, when the object moves so as to narrow the space, the inhibition information may be generated assuming that the object is an obstructing object. Then, the generated inhibition information may be acquired.

According to such a merging support system 10, since the merging support system 10 mounted on the own vehicle 1 identifies that it is an obstructive object, an unintended operation such as suddenly interrupting in front of the own vehicle 1 is performed. Even if there is a vehicle that does, the object can be detected as an obstructive object in the own vehicle 1. That is, the obstructive object can be detected more quickly and the caution information can be output more quickly than when the obstructive object is detected via the roadside infrastructure or the center.

(1e) In the above-mentioned merging support system 10, the control unit 50 may determine whether or not the object is located immediately before the own vehicle 1 in the first lane 61 based on the position of the object. You may also get the velocity of the object. Then, when the object is located in front of the own vehicle 1 in the first lane 61 and the speed of the object decreases with the passage of time, it may be determined that the object moves so as to narrow the space.

According to such a merging support system 10, for example, as shown in FIG. 7, even when the vehicle 4 immediately before the own vehicle 1 suddenly decelerates and the space 81 in front becomes narrow, the vehicle immediately before the merging support system 10. 4 can be detected as an obstructive object.

(1f) In the above-mentioned merging support system 10, the control unit 50 is an object in an anti-adjacent lane 63 which is a lane adjacent to the first lane 61 and is located opposite to the second lane 62 based on the position of the object. May be determined whether or not is located.

According to such a merging support system 10, it is possible to detect that an object is located in the anti-adjacent lane 63.
(1g) In the above-mentioned merging support system 10, the control unit 50 may acquire the inter-lane distance 631 indicating the distance between the object and the first lane 61. Then, when the object is located in the anti-adjacent lane 63 and the inter-lane distance 631 decreases with the passage of time, it may be determined that the object moves so as to narrow the space.

According to such a merging support system 10, although not shown, the vehicle gradually approaches the first lane 61 from the anti-adjacent lane 63 without announcing a lane change to the first lane 61 by a turn signal or the like. Even if a vehicle is present, the vehicle can be detected as an obstructive object.

(1h) In the above-mentioned merging support system 10, the control unit 50 may acquire an image of the surroundings of the own vehicle 1. Further, it may be determined whether or not the object included in the image is a vehicle expressing a lane change to the first lane 61. Then, when the object is located in the anti-adjacent lane 63 and the object is a vehicle expressing a lane change to the first lane 61, it may be determined that the object moves so as to narrow the space.

According to such a merging support system 10, for example, as shown in FIG. 7, when there is a vehicle 8 that announces a lane change to the first lane 61 and suddenly tries to interrupt the first lane 61. In addition, the vehicle can be detected as an obstructive object.

(1i) The caution information may include, for example, a message such as notifying the driver that an obstructing object is present. As a result, it is possible to call attention to other vehicles that have received the caution information. In addition, the caution information may include a part or all of the obstruction vehicle information. As a result, the obstructed vehicle information can be used by other vehicles that have received the caution information in order to recognize the obstructed vehicle.

For example, the inhibition vehicle information may include information indicating an inhibition pattern. According to this, the merging vehicle can adjust the vehicle speed and the merging position according to the obstruction pattern so as to avoid a collision with the obstructing vehicle in the space 81 in front. That is, it is possible to make the merging vehicle merge more safely.

Further, for example, the inhibition vehicle information may include the degree of inhibition. According to this, when the degree of obstruction is large, the merging vehicle can adjust the vehicle speed and the merging position so as to avoid a collision with the obstructing vehicle in the space 81 in front. Further, the merging vehicle may not perform the adjustment when the degree of inhibition is small. That is, it is possible to make the merging vehicle perform the control necessary for merging according to the degree of inhibition.

In addition, the obstruction vehicle information may include information indicating the appearance characteristics of the obstruction vehicle such as the color and shape of the vehicle body of the obstruction vehicle. This makes it easier for drivers of other vehicles to visually recognize the obstructed vehicle [2. Second Embodiment]
[2-1. Differences from the first embodiment]
Since the basic configuration of the second embodiment is the same as that of the first embodiment, the differences will be described below. The same reference numerals as those in the first embodiment indicate the same configurations, and the preceding description will be referred to.

In the second embodiment, in addition to the first embodiment, before the own vehicle 1 reaches the merging area 71, the distance to the own vehicle 1 is set with respect to other vehicles located around the own vehicle 1. It differs from the first embodiment in that an instruction is output so that the platoon distance is set to a predetermined value.

[2-2. processing]
Next, the platooning process executed by the control unit 50 of the second embodiment in addition to the merging support process of the first embodiment shown in FIG. 3 will be described with reference to the flowchart of FIG. The platooning process is started, for example, when the power of the merging support system 10 is turned on, and is repeated thereafter.

In the following description, it is assumed that the merging vehicle 9 can communicate with the own vehicle 1 by, for example, vehicle-to-vehicle communication, wireless communication via a center, roadside infrastructure, or the like. Further, it is assumed that the other vehicles located around the own vehicle 1 other than the merging vehicle 9 include both a vehicle capable of communicating with the own vehicle 1 and a vehicle not capable of communicating with the own vehicle 1. Further, as shown in FIG. 9, it is assumed that the own vehicle 1 is traveling in the first lane 61 toward the merging area 71.

In S210, the control unit 50 acquires the reachable distance. The reachable distance indicates the distance from the own vehicle 1 to the merging area 71. More specifically, the reachable distance indicates the distance from the own vehicle 1 to the merging start position 711. The reachable distance may be calculated based on the current position of the own vehicle 1 acquired in S10 and the road data 151.

In S215, the control unit 50 detects a communicable vehicle. Specifically, the control unit 50 transmits vehicle-to-vehicle communication information regarding the own vehicle 1 to vehicles located around the own vehicle 1 by inter-vehicle communication. Vehicle-to-vehicle communication information may include information such as vehicle number, current position, speed, and the like. The control unit 50 may use the own vehicle 1 information acquired in S10 in the above-mentioned merging support process as the inter-vehicle communication information regarding the own vehicle 1. The periphery of the own vehicle 1 referred to here may include, for example, a range in which inter-vehicle communication with the own vehicle 1 is possible.

As shown in FIG. 10, other vehicles 5a and 5b equipped with a wireless communication device for vehicle-to-vehicle communication such as the vehicle-to-vehicle communication device 20 also have vehicles related to the other vehicles 5a and 5b. Vehicle-to-vehicle communication information is transmitted at a predetermined cycle.

The control unit 50 generates a communication vehicle list in S220. The communication vehicle list indicates information in which the vehicle number of the vehicle capable of inter-vehicle communication and the current position and speed of the vehicle are associated with each vehicle number for the vehicle capable of inter-vehicle communication.

Each time the control unit 50 receives vehicle-to-vehicle communication information from another vehicle by vehicle-to-vehicle communication, the control unit 50 adds vehicle-to-vehicle communication information related to the other vehicle to the communication vehicle list, and adds the added communication vehicle list to a new communication vehicle. It is recorded in the memory 52 as a list. In addition, even if the other vehicle is included in the communication vehicle list, if the vehicle-to-vehicle communication information is not received from the other vehicle for a predetermined period, the information about the other vehicle is deleted from the communication vehicle list. The deleted communication vehicle list is recorded in the memory 52 as a new communication vehicle list.

In S225, the control unit 50 determines whether or not the reachable distance is less than the designated distance. The indicated distance indicates a predetermined value and is recorded in the memory 52 in advance. The indicated distance may include, for example, a distance of several kilometers to a dozen kilometers. As shown in FIG. 9, the instruction start position 731 described below indicates a position separated from the merging area 71 by an instruction distance 72. The term "front" here means the side opposite to the traveling direction of the own vehicle 1.

That is, the control unit 50 shifts the processing to S230 when the instruction start position 731 is reached, and ends the main formation processing when the instruction start position 731 is not reached.
In S230, the control unit 50 determines whether or not the own vehicle 1 is located in the platoon area based on the current position of the own vehicle 1 and the road data 151. As shown in FIG. 9, the formation area 73 indicates the range from the instruction start position 731 to the merging area 71 and the merging area 71 combined.

The control unit 50 ends the main formation process when the own vehicle 1 is not located in the formation area 73, and shifts the processing to S235 when it is located in the formation area 73.
In S235, the control unit 50 determines whether or not the merge request has been received. The merging request is information transmitted from the merging vehicle 9 as shown in FIG. 11, and indicates that the merging vehicle 9 is scheduled to merge in the merging area 71 and requests support for the merging. Represents information. The control unit 50 may specify the merging vehicle 9 based on the vehicle-to-vehicle communication information obtained by the vehicle-to-vehicle communication. Alternatively, the control unit 50 may specify the merging vehicle 9 based on the surrounding information acquired in S15 and the road data 151.

For example, as shown in FIG. 9, the merging vehicle 9 may send a merging request after passing through the tollhouse 621 in the second lane 62. If the merge request is received, the process is shifted to S240, and if it is not received, the main formation process is terminated.

The control unit 50 determines whether or not the formation is possible in S240. The term "platoon" as used herein means that the own vehicle 1 and other vehicles located around the own vehicle 1 travel at a predetermined distance so as to secure a space 81 in front of the own vehicle 1. .. Securing the space 81 in front of the own vehicle 1 means that the space 81 in front is not narrowed.

For example, the control unit 50 may acquire a communication vehicle list and determine that platooning is possible when a vehicle capable of inter-vehicle communication (hereinafter referred to as a communicable vehicle) is included in the communication vehicle list. The control unit 50 shifts the process to S245 when the formation is possible, and shifts the process to S270 when the formation is not possible.

In S245, the control unit 50 outputs a formation instruction to communicable vehicles located around the own vehicle 1 by vehicle-to-vehicle communication. The platooning instruction represents an instruction for the communicable vehicle to maintain the distance from the own vehicle 1 at the platooning distance. The platoon distance is a predetermined distance and is recorded in the memory 52 in advance. The platoon distance may include, for example, a distance of several tens of meters to a hundred and several tens of meters.

The platoon distance may be represented by the distance from the own vehicle 1 in the extending direction of the road (hereinafter, the distance in the road direction) and the distance from the own vehicle 1 in the width direction of the road (hereinafter, the distance in the width direction). ..

Further, the platoon distance may be a value set for each communication vehicle for which the platoon instruction is output. According to this, since the formation distance is set and output for each target communication vehicle, an arbitrary formation is formed so as to secure a space 81 in front by the own vehicle 1 and the target communication vehicle. Can be done.

The platooning instructions may include the platooning distance, the speed at which the platooning distance is maintained. Further, as shown in FIG. 11, for example, the platooning instruction may include a position with respect to the own vehicle 1 specified based on the platooning distance instead of the platooning distance.

Here, it is assumed that the communicable vehicle that has received the platoon instruction is configured to transmit a response to the effect that it understands the platoon instruction when it is possible to travel based on the platoon instruction. For example, a communicable vehicle that has received a platoon instruction is a communicable vehicle when there are no other vehicles around the communicable vehicle or when all the other vehicles located around the communicable vehicle are communicable vehicles. You may send a response to your understanding of the formation instructions.

In S250, the control unit 50 determines whether or not the formation is completed by the confluence area 71. Specifically, the control unit 50 determines that the formation is completed when a response to the effect that the formation instruction output in S245 is understood is received from the communicable vehicle by vehicle-to-vehicle communication. The control unit 50 shifts the process to S270 when the formation is not completed, and shifts the process to S255 when the formation is completed.

In this step, the control unit 50 may transmit the merged vehicle information to the merged vehicle 9 as shown in FIG. The merged vehicle information indicates information about the merged vehicle. The merging vehicle refers to a vehicle that travels with a space 81 in front for the merging vehicle 9 merging. In the present embodiment, the own vehicle 1 corresponds to the merged vehicle.

The information referred to here may include a vehicle number, information indicating appearance characteristics of the vehicle such as the color and shape of the vehicle body, a vehicle type, and the like. The merging vehicle 9 can execute merging into the space 81 in front of the own vehicle 1 while specifying the own vehicle 1 based on the information on the merging vehicle.

In S260, the control unit 50 determines whether or not the merging completion notification has been received from the merging vehicle 9 by vehicle-to-vehicle communication. The merging completion notification is a notification indicating that the merging vehicle 9 has completed the movement from the second lane 62, which is a branch line, to the first lane 61, which is the main line. The control unit 50 waits until it receives the merge completion notification, and after receiving the merge completion notification, shifts the process to S265.

In S265, the control unit 50 outputs an instruction to release the formation to a communication vehicle located around the own vehicle 1 by vehicle-to-vehicle communication. Then, the main formation processing is completed.
In S270, the control unit 50 outputs a merge refusal notification to the merge vehicle 9 by vehicle-to-vehicle communication. The merge refusal notice represents a notice indicating that it is difficult to provide merge support. After outputting the communication, the control unit 50 ends the main formation processing.

[2-3. effect]
According to the second embodiment described in detail above, the effects (1a) to (1i) of the above-mentioned first embodiment are achieved, and the following effects are further achieved.

(2a) In the above-mentioned merging support system 10, the control unit 50 may acquire the reachable distance indicating the distance from the own vehicle 1 to the merging area 71. Then, when the reach distance is less than the designated distance indicating the predetermined distance, the vehicle around the own vehicle 1 is wirelessly communicated with the platoon instruction to maintain the distance from the own vehicle 1 at the predetermined platoon distance. May be output by.

According to such a merging support system 10, vehicles around the own vehicle 1 are allowed to run while maintaining the distance to the own vehicle 1 at the platoon distance with an interval that does not cause overtaking or interruption as the platoon distance. It can be expected to suppress the occurrence of obstructive vehicles.

That is, as shown in FIG. 13, for example, by outputting the formation instruction to the communication vehicles 7a and 7b located around the own vehicle 1, the space 81 in front of the own vehicle 1 is secured. According to this, for example, it becomes difficult for another vehicle 6 located in the anti-adjacent lane 63 to cut into the space 81 in front of the vehicle, so that the merging vehicle 9 can safely merge.

Although not shown, the formation instruction may be output to, for example, at least a communication vehicle immediately after the own vehicle 1 in the first lane 61 (hereinafter, a vehicle immediately after). According to this, it becomes difficult for another vehicle in the anti-adjacent lane 63, which is located behind the own vehicle 1 and the vehicle immediately after, to cut into the space 81 in front of the merging vehicle 9. Can be safely merged.

However, the formation instruction is not limited to these, and may be output to any vehicle so that it is difficult for another vehicle to cut into the space 81 in front.
[3. Other embodiments]
Although the embodiments of the present disclosure have been described above, the present disclosure is not limited to the above-described embodiments, and can be implemented in various modifications.

(3a) In the above embodiment, the merging area information is generated in the merging support system 10, but the merging area information may be acquired from the roadside infrastructure, the center, or the like by wireless communication.

(3b) In the above embodiment, the inhibition information is generated in the merging support system 10, but for example, the inhibition information is generated in another vehicle located around the own vehicle 1, and the inhibition information is generated between vehicles. It may be acquired by communication. Alternatively, the inhibition information generated by another vehicle may be acquired via the roadside infrastructure, the center, or the like.

(3c) In the above embodiment, the camera 13 captures the surroundings of the own vehicle 1, but the range of imaging is not limited to this. The camera 13 may image the front or rear of the own vehicle 1, may image the right or left of the own vehicle 1, or may image any combination thereof. You may.

(3d) In the above embodiment, the indicated distance indicates a predetermined value, but the indicated distance is not limited to this. The indicated distance may be calculated by the control unit 50 based on the speed of the own vehicle 1 in the first lane 61, which is the main line. Specifically, the indicated distance may be calculated as a value obtained by integrating the time required for the merging vehicle 9 to reach the merging area 71 from the tollhouse and the speed of the own vehicle 1.

That is, in FIG. 9, the distance from the tollhouse 621 to the confluence point 622 in the second lane 62, that is, the distance of the ramp way 64 is d1 km, and the speed limit in the second lane 62 is v1 km / h. In this case, the time required for the merging vehicle 9 to reach the merging point 622 from the tollhouse 621 is calculated as (d1 / v1) time. The merging vehicle 9 shall transmit the merging request after passing through the tollhouse 621.

Here, when the speed of the own vehicle 1 traveling on the first lane 61, which is the main line, is v2 km / h, the indicated distance may be calculated as (d1 / v1) × v2 km. As a result, the indicated distance 72 can be set for each merging area 71 according to the road configuration. Therefore, the appropriate timing that is neither too early nor too late than when the indicated distance 72 is set to a predetermined value. You can send platoon instructions at.

(3e) In the above embodiment, for example, the own vehicle 1 and the communication vehicles 7a and 7b shown in FIG. 13 may be vehicles having an automatic driving function such as an ACC function. ACC is an abbreviation for Adaptive Cruise Control. ACC is a function that causes a vehicle to automatically run at a constant speed while keeping the distance between vehicles constant. The communication vehicles 7a and 7b may use the vehicle speed instructed by the platoon instruction as the vehicle speed in the ACC.

(3f) A plurality of functions possessed by one component in the above embodiment may be realized by a plurality of components, or one function possessed by one component may be realized by a plurality of components. .. Further, a plurality of functions possessed by the plurality of components may be realized by one component, or one function realized by the plurality of components may be realized by one component. Further, a part of the configuration of the above embodiment may be omitted. In addition, at least a part of the configuration of the above embodiment may be added or replaced with the configuration of the other above embodiment. It should be noted that all aspects included in the technical idea specified from the wording described in the claims are embodiments of the present disclosure.

(3g) In various forms such as the above-mentioned merging support system 10, the control unit 50, a program for operating the control unit 50, a non-transitional actual recording medium such as a semiconductor memory in which this program is recorded, and a merging support method. The present disclosure can also be realized.

[4. Correspondence between the configuration of the embodiment and the configuration of the present disclosure]
In the above embodiment, the control unit 50 in the merging support system 10 corresponds to the merging support device referred to in the present disclosure. The vehicle-to-vehicle communication device 20 and the wireless communication device 30 correspond to the communication devices referred to in the present disclosure. The control unit 50 is an object acquisition unit, a speed acquisition unit, a direction determination unit, an obstruction acquisition unit, a confluence acquisition unit, an output unit, an immediately preceding determination unit, an adjacency determination unit, a lane acquisition unit, a direction determination unit, and an inhibition generation unit in the present disclosure. Corresponds to the department, image acquisition unit, image judgment unit, arrival acquisition unit, and formation instruction unit.

Further, S15 corresponds to the processing as the object acquisition unit and the speed acquisition unit, S20 corresponds to the processing as the direction determination unit, S45 corresponds to the processing as the inhibition acquisition unit, and S50 corresponds to the processing as the confluence acquisition unit. Corresponds to, and S65 corresponds to the processing as an output unit. Further, S100 corresponds to the processing as the immediately preceding determination unit, S120 corresponds to the processing as the adjacent determination unit, S130 corresponds to the processing as the lane acquisition unit, and S110, S135, and S150 correspond to the processing as the direction determination unit. Corresponds to.

Further, S115, S140, and S155 correspond to the processing as the inhibition generation unit, S145 corresponds to the processing as the image acquisition unit, S150 corresponds to the processing as the image determination unit, and S210 corresponds to the processing as the arrival acquisition unit. Corresponds to, and S245 corresponds to the processing as a formation instruction unit.

Further, in the above embodiment, the vehicle and other vehicles correspond to the objects referred to in the present disclosure, and the obstructing vehicle corresponds to the obstructing object referred to in the present disclosure.

20 vehicle-to-vehicle communication device, 30 wireless communication device, 50 control unit.

Claims (7)

An obstruction acquisition unit (S45) configured to acquire obstruction information indicating that an obstructive object indicating an object moving so as to narrow the space ahead in the lane in which the own vehicle is traveling exists around the own vehicle. ,
Acquires merging area information indicating that the own vehicle is located in the merging area representing the area where the second lane indicating a lane different from the first lane merges with the first lane indicating the lane in which the own vehicle is traveling. Confluence acquisition unit (S50) configured to do
An output unit (S65) configured to output caution information that calls attention when the confluence region information is acquired and the inhibition information is acquired.
An object acquisition unit (S15) configured to acquire the moving direction and position of an object, and
A direction determination unit (S20, S110, S135, S150) configured to determine whether or not the object moves so as to narrow the space based on the moving direction and position of the object.
Inhibition generating units (S115, S140, S155) configured to generate the inhibition information assuming that the object is the inhibition object when the object moves so as to narrow the space.
Adjacent configured to determine whether or not the object is located in an anti-adjacent lane that is adjacent to the first lane and is located opposite to the second lane based on the position of the object. Judgment unit (S120) and
A lane acquisition unit (S130) configured to acquire a distance between lanes indicating a distance between an object and the first lane.
With
The inhibition acquisition unit is configured to acquire the inhibition information generated by the inhibition generation unit .
The direction determination unit (S135) determines that when an object is located in the anti-adjacent lane and the distance between the lanes decreases with the passage of time, the object moves so as to narrow the space. Confluence support device (50) configured in . The merging support device according to claim 1 .
An image acquisition unit (S145) configured to acquire an image of the surroundings of the own vehicle, and
An image determination unit (S150) configured to determine whether or not the object included in the image is a vehicle expressing a lane change to the first lane.
With more
The direction determination unit (S150) narrows the space when the object is located in the anti-adjacent lane and the object is a vehicle expressing a lane change to the first lane. A merging support device configured to determine that it will move. An obstruction acquisition unit (S45) configured to acquire obstruction information indicating that an obstructive object indicating an object moving so as to narrow the space ahead in the lane in which the own vehicle is traveling exists around the own vehicle. ,
Acquires merging area information indicating that the own vehicle is located in the merging area representing the area where the second lane indicating a lane different from the first lane merges with the first lane indicating the lane in which the own vehicle is traveling. Confluence acquisition unit (S50) configured to do
An output unit (S65) configured to output caution information that calls attention when the confluence region information is acquired and the inhibition information is acquired.
An object acquisition unit (S15) configured to acquire the moving direction and position of an object, and
A direction determination unit (S20, S110, S135, S150) configured to determine whether or not the object moves so as to narrow the space based on the moving direction and position of the object.
Inhibition generating units (S115, S140, S155) configured to generate the inhibition information assuming that the object is the inhibition object when the object moves so as to narrow the space.
Adjacent configured to determine whether or not the object is located in an anti-adjacent lane that is adjacent to the first lane and is located opposite to the second lane based on the position of the object. Judgment unit (S120) and
An image acquisition unit (S145) configured to acquire an image of the surroundings of the own vehicle, and
An image determination unit (S150) configured to determine whether or not the object included in the image is a vehicle expressing a lane change to the first lane.
With
The inhibition acquisition unit is configured to acquire the inhibition information generated by the inhibition generation unit .
The direction determination unit (S150) narrows the space when the object is located in the anti-adjacent lane and the object is a vehicle expressing a lane change to the first lane. A merging support device (50) configured to determine that it will move . The merging support device according to any one of claims 1 to 3 .
The output unit is a merging support device configured to output the caution information by wireless communication using communication devices (20, 30) that perform wireless communication. The merging support device according to claim 4 .
The communication device (20) is a vehicle-to-vehicle communication device representing a device that performs wireless communication between another vehicle indicating another vehicle different from the own vehicle and the own vehicle.
The output unit is a merging support device configured to output the caution information by vehicle-to-vehicle communication using the vehicle-to-vehicle communication device. The merging support device according to any one of claims 1 to 5 .
Immediately preceding determination unit (S100) configured to determine whether or not the object is located immediately before the own vehicle in the first lane based on the position of the object.
A velocity acquisition unit (S15) configured to acquire the velocity of the object, and
With more
The direction determination unit (S110) narrows the space when the object is located in front of the own vehicle in the first lane and the speed of the object decreases with the passage of time. A merging support device configured to determine that it will move. The merging support device according to any one of claims 1 to 6.
A reach acquisition unit (S210) configured to acquire a reach indicating the distance from the own vehicle to the confluence region, and
When the reach is less than the specified distance indicating a predetermined distance, a platooning instruction for maintaining the distance to the own vehicle at a predetermined platooning distance is output by wireless communication to vehicles around the own vehicle. With the formation command unit (S245) configured as
A merging support device further equipped with.